Configuring a distributed antenna system

ABSTRACT

Systems and methods for developing a configuration plan for communication transport links of a distributed antenna system are provided. The distributed antenna system includes a unit communicating with remote antenna units over the communication transport links. The unit receives signals from base stations. Characteristics of each of the signals are determined. The characteristics include, for each signal, a frequency occupancy, a digital bandwidth, and a coverage zone to which to provide the signal. The frequency occupancy includes the minimum frequency component and the maximum frequency component of the signal. The digital bandwidth is a bandwidth for communicating the signal via the communication transport links. A hardware capability of the distributed antenna system, such as a respective available bandwidth for each communication transport link, is also determined. The configuration plan for transporting the digital representations of the signals is determined based on the hardware capability and the characteristics of the signals.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No.13/597,900 filed Aug. 29, 2012, and titled “Configuring a DistributedAntenna System,” which claims the benefit of U.S. ProvisionalApplication Ser. No. 61/528,310 filed on Aug. 29, 2011, and titled“Configuring a Distributed Antenna System,” wherein the contents of allof the foregoing applications are hereby incorporated by reference.

TECHNICAL FIELD

The present invention relates generally to telecommunications and, moreparticularly (although not necessarily exclusively), to systems andmethods for configuring a distributed antenna system.

BACKGROUND

A distributed antenna system (“DAS”) can be used to extend the coverageof a cellular communication system to areas of traditionally low signalcoverage, such as within buildings, tunnels, or in areas obstructed byterrain features. A DAS can extend coverage by receiving signals from abase station of a cellular communication system and re-transmitting thesignals directly into low-coverage areas. A DAS can include a masterunit in communication with carrier systems, such as base stations ofcellular service providers, and a group of remote antenna units. Theremote antenna units can be physically separate from the master unit,but in communication with the master unit over a serial link. A remoteantenna unit can wirelessly communicate signals to wireless devicespositioned in a coverage area.

The master unit can receive signals from multiple base stations. Signalsfrom different base stations may have frequencies within commonfrequency bands. Signals from different base stations may also beprovided to different remote antenna units.

The DAS can include communication transport links between a master unitand the remote antenna units. The communication transport links canprovide signal paths between a base station and the remote antennaunits. Configuring the DAS by determining the communication transportlinks over which signals are provided can be difficult.

One method for assigning signals to communication transport links useshardware included in each communication transport link. For example, theDAS can include RF switches and a switching matrix for a technician toassign signals from multiple base stations to specific communicationtransport links. Hardware-based solutions may be impractical and costlyas the size and complexity of a DAS increases, such as for a DAS havingcomplex systems of many remote antenna units. For example, hardware maylack flexibility that is helpful in accounting for system changes.Furthermore, modifying the configuration subsequent to deployment can bedifficult generally, and impossible to complete while allowing the DASto continue to function.

Accordingly, systems and methods are desirable for configuringcommunication transport links of a DAS.

SUMMARY

In one aspect, a method for developing a configuration plan forcommunication transport links of a distributed antenna system isprovided. The distributed antenna system includes a unit incommunication with remote antenna units over the communication transportlinks. The unit can receive signals from at least one base station. Themethod involves determining characteristics of each of the signals. Thecharacteristics for each signal can include a respective frequencyoccupancy of the signal, a respective digital bandwidth of the signal,and a respective coverage zone to which to provide the signal. Thefrequency occupancy can include the minimum frequency component and themaximum frequency component of the signal. The digital bandwidth caninclude a bandwidth for communicating the signal via the communicationtransport links. The method also involves determining a hardwarecapability of the distributed antenna system. The hardware capabilityincludes a respective available bandwidth for each communicationtransport link. The method also involves determining the configurationplan based on the hardware capability and the characteristics of thesignals. The configuration plan specifies a configuration of thecommunication transport links for transporting the digitalrepresentations of the signals. The method also involves outputting theconfiguration plan.

In another aspect, a system for developing a configuration plan of adistributed antenna system is provided. The system includes a unit and aprocessor disposed in the unit. The unit can receive signals from a basestation and communicate the signals to remote antenna units viacommunication transport links of the distributed antenna system. Theprocessor can determine an association of coverage zones with coveragesets. Each coverage zone represents a subset of the remote antennaunits. Each coverage set includes band sets to be provided to a commoncoverage zone. Each band set includes a subset of the signals. Each bandset is represented by a band stream. The processor can also determine ahardware capability of the distributed antenna system. The hardwarecapability includes a respective available bandwidth for eachcommunication transport link. The processor can also determine theconfiguration plan based on the available bandwidth of eachcommunication transport link, a respective frequency occupancy of eachband set, a respective digital bandwidth of each band set, andassociations between the coverage zones and the respective coveragesets. The frequency occupancy for the band set includes the minimumfrequency component and the maximum frequency component of the signalsof the band sets. The digital bandwidth includes a bandwidth forcommunicating the signal via the respective communication transportlink. The processor can also output the configuration plan.

In another aspect, a distributed antenna system is provided. Thedistributed antenna system includes remote antenna units grouped intocoverage zones and a unit in communication with the remote antenna unitsover communication transport links. Each coverage zone includes a subsetof the remote antenna units. The unit includes a configuration module.The configuration module is configured for determining characteristicsof signals. The characteristics for each signal can include a respectivefrequency occupancy of the signal, a respective digital bandwidth of thesignal, and a respective coverage zone to which to provide the signal.The frequency occupancy can include the minimum frequency component andthe maximum frequency component of the signal. The digital bandwidth caninclude a bandwidth for communicating the signal via the communicationtransport links. The configuration module is also configured fordetermining a hardware capability of the distributed antenna system. Thehardware capability includes a respective available bandwidth for eachcommunication transport link. The configuration module is alsoconfigured for determining a configuration plan based on the hardwarecapability and the characteristics of the signals. The configurationplan specifies a configuration of the communication transport links fortransporting the digital representations of the signals. Theconfiguration module is also configured for outputting the configurationplan.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram of a distributed antenna system in which aconfiguration module for configuring the distributed antenna system isdisposed according to one aspect.

FIG. 2 is a functional block diagram of a configuration module accordingto one aspect.

FIG. 3 is a flow chart illustrating a process for configuring adistributed antenna system according to one aspect.

FIG. 4 is a modeling diagram illustrating assignment of band sets tocoverage zones via coverage sets by a unit according to one aspect.

FIG. 5 is a flow chart illustrating a process for configuringcommunication transport links of a distributed antenna system based onthe available bandwidth of the communication transport links accordingto one aspect.

FIG. 6 is a flow chart illustrating a process for configuringcommunication transport links of a distributed antenna system based onbandwidth of band sets according to one aspect.

FIG. 7 is a flow chart illustrating a process for configuring thecommunication transport links using common band sets, shared band sets,and zone-specific band sets according to one aspect.

DETAILED DESCRIPTION

Certain aspects and examples of the present invention are directed to aconfiguration module for a DAS that can automatically develop a plan forconfiguring communication transport links in the DAS. The configurationmodule can be disposed in a unit of the DAS, such as (but not limited) amaster unit. The unit can communicate signals from one or more basestations to the remote antenna units over the communication transportlinks, either directly or via one or more extension units. Theconfiguration module can determine characteristics for each signal, suchas a respective frequency occupancy of the signal, a respective digitalbandwidth of the signal, and a respective coverage zone to which toprovide the signal. The configuration module can also determine arespective available bandwidth for each communication transport link aswell as other hardware capabilities for the DAS. The configurationmodule can generate and output a configuration plan for thecommunication transport links based on the hardware capability andcharacteristics. The configuration plan can include an assignment ofsignals communicated via the unit to communication transport linksbetween the unit and the remote antenna units, communication transportlinks between the unit and an extension unit, and/or communicationtransport links between the extension unit and the remote antenna units.

As used herein, the term “communication transport link” can include oneor more physical connections providing a signal path between devices ina telecommunication system, such as (but not limited to) master unitsand remote antenna units of a DAS. A communication transport link caninclude any type of communication medium over which signals can becommunicated between devices in a telecommunication system. Non-limitingexamples of suitable communication mediums include copper cable (such asa coaxial cable), optical fiber, and microwave link. A communicationtransport link can have characteristics that limit the number of signalsthat can be provided over the communication transport link. Anon-limiting example of such characteristics includes the totalbandwidth of signal transportation provided by the communicationtransport link.

As used herein, the term “bandwidth” can include an analog bandwidth ora digital bandwidth. An analog bandwidth can be associated with ananalog signal received by a distributed antenna system from a basestation. A digital bandwidth can be associated with a digital signalcommunicated via the communication transport links of a distributedantenna system. For example, an analog signal communicated via an analogfrequency channel having an analog bandwidth of 5 MHz may becommunicated via a digital link having a digital bandwidth of 60 MHz.

As used herein, the term “the frequency occupancy” can include a rangeof frequencies for frequency components of a signal or a group ofsignals. The frequency occupancy of a signal or a group of signals caninclude (or be described with respect to) the minimum frequencycomponent of the signal and a maximum frequency component of the signal.

As used herein, the term “assignment of signals” can include identifyingone or more coverage zones to which a signal will be provided,associating the coverage zones with coverage sets, and determining thecommunication transport link over which to provide each coverage set toits associated coverage zone.

As used herein, the term “coverage zone” can include a geographical areain a telecommunication system, such as a DAS, in which wireless devicescan communicate with one or more remote antenna units providing signalcoverage to the geographical area. Each remote antenna unit can beassigned to a coverage zone. In some aspects, sub-sets of the remoteantenna units within a coverage zone may be assigned to transmitdifferent sub-sets of a group of signals provided to the coverage zone.

As used herein, the term “coverage set” can include a grouping of bandsets to be provided to a coverage zone. Each coverage set may beassociated with one or more coverage zones.

As used herein, the term “band set” can include a set of signals havingan association with a common coverage zone. A band set can include thesignals from one or more base stations. A band set can include a set ofsignals having a common frequency band. In additional or alternativeaspects, a band set can include signals from individual channels ofassigned frequency bands. The individual channels of assigned frequencybands can be channels from different frequency bands, such as RF bands.The band set may include signals from multiple channels from respectivemultiple frequency bands. In additional or alternative aspects, a bandset can include signals from individual channels from differentfrequency bands mapped to a common base band. In additional oralternative aspects, signals from base stations can be combined intoband sets based on the bandwidth of the signals, the start frequenciesof the signals, and the stop frequencies of the signals.

Signals can be transmitted via the DAS as digital data streamsrepresenting the signals received from the base stations. A digital datastream can include a series of digital samples representing a signal.The signals transmitted via the DAS can be grouped into band sets.Grouping the signals into band sets can include combining digital datastreams representing signals in a given frequency band into a combinedsignal that is a band stream. The band stream may be a single digitaldata stream representing the combined signals included in the band set.The band stream may have a band stream bandwidth. The band streambandwidth can include the combined bandwidths of the signals of the bandset represented by the band stream.

A configuration module can develop a plan for configuring thecommunication transport links based on the hardware capability of theDAS and characteristics of the signals transported via the DAS.Non-limiting examples of the hardware capability of the DAS can includeone or more of the number of communication transport links between eachunit and each remote antenna unit, the maximum bandwidth that can beprovided over each communication transport link, the maximum number ofband streams capable of being provided over each of the communicationtransport links, etc. Non-limiting examples of characteristics of thesignals transported via the DAS include one or more of the bandwidth ofeach signal, the bandwidth of each band stream included in a coverageset, the coverage zone to which the coverage set is being provided, etc.

In some aspects, the configuration module can develop the plan based onan association of coverage zones with coverage sets by sorting the bandsets in a coverage set based on the bandwidth of each band set. Bandsets can sorted from largest to smallest bandwidth. The configurationmodule can assign each band set to a communication transport link inorder of decreasing bandwidth until either the maximum bandwidth of thecommunication transport link or maximum number of band sets that can beprovided over the communication transport link is reached. If noadditional band sets can be provided over the first communicationtransport link, the configuration module can select a secondcommunication transport link and continue assigning band sets indecreasing order of the bandwidth of the sorted band sets. Theconfiguration can iteratively continue this process until all band setsare assigned or until no more communication transport links areavailable.

In other aspects, the configuration module can group the band sets in acoverage set into separate subsets for common band sets, shared bandsets, and zone-specific band sets. Common band sets can include bandsets that are provided to all of the coverage zones in a DAS. Sharedband sets can include band sets that are provided to more than one butfewer than all of the coverage zones in a DAS. Zone-specific band setscan include band sets that are provided to a single coverage zone in aDAS. The configuration module can assign all common band sets in orderof decreasing bandwidth to communication transport links, assign allshared band sets in order of decreasing bandwidth, and assignzone-specific band sets in order of decreasing bandwidth.

The configuration module can output the plan via any suitable mechanism,such as providing the plan for display in a graphical user interface.The outputted plan can be used to select each communication transportlink over which the unit can provide each band set to each of thedestination coverage zone. In other aspects, outputting the plan caninclude a system controller automatically executing the plan for theDAS.

Detailed descriptions of these aspects and examples are discussed below.These illustrative examples are given to introduce the reader to thegeneral subject matter discussed here and are not intended to limit thescope of the disclosed concepts. The following sections describe variousadditional aspects and examples with reference to the drawings in whichlike numerals indicate like elements, and directional descriptions areused to describe the illustrative examples but, like the illustrativeexamples, should not be used to limit the present invention.

FIG. 1 depicts a DAS 10 in which a configuration module 26 forconfiguring the DAS 10 is disposed. The DAS 10 can include a unit 14,extension units 16 a-b, and remote antenna units 18 a-h. The DAS 10 canbe positioned in an area of low signal coverage, such as the interior ofa building, to extend wireless communication coverage. Extendingwireless coverage can include communicating signals between basestations 12 a-n and wireless devices positioned in a coverage area ofthe DAS 10.

The DAS 10 can receive downlink signals from one or more base stations12 a-n via a wired or wireless communication medium. The DAS 10 can alsoprovide uplink signals to the base stations 12 a-n.

The unit 14 can communicate uplink and downlink signals between the basestations 12 a-n and one or more remote antenna units 18 a-h distributedin the environment to provide coverage within a service area of the DAS10. A non-limiting example of a unit 14 is a master unit, such as (butnot limited to) a digital conversion station.

The unit 14 can convert downlink signals received from the base stations12 a-n, such as RF signals, into one or more digital data streams. Agroup of signals represented by digital data streams can form a bandset. The unit 14 can include circuitry, such as summers or multiplexers,configured to combine the digital data streams within a band set into aband stream. The band stream may be a single digital data stream thatincludes the digital data streams representing the signals in a bandset. In some aspects, combining the digital data streams can includesumming or adding signals within a band set. In other aspects, combiningthe digital data streams can include multiplexing the digital datastreams into a serialized band stream.

The unit 14 can provide downlink signals, such as digital data streams,to the remote antenna units 18 a-d via one or more extension units 16a-b. A non-limiting example of an extension unit is a transportextension node. The extension units 16 a-b can extend the range of theunit 14. For example, a unit 14 may transmit optical downlink signalsover an optical fiber link to extension units 16 a-b. The extensionunits 16 a-b can convert the optical downlink signals to electricaldownlink signals and provide the electrical downlink signals to remoteantenna units 18 a-d over a copper cable, such as a coaxial cable, orother suitable communication medium.

The unit 14 can also directly provide downlink signals to the remoteantenna units 18 e-h. Directly providing downlink signals can include,for example, communicating the downlink signals from the unit 14 to theremote antenna units 18 e-h without the downlink signals being receivedby a separate communication device, such as a transport extension nodeor other device, in the signal path between the unit 14 and a remoteantenna unit.

The remote antenna units 18 a-h can convert digital data streams to RFsignals. The remote antenna units 18 a-h can amplify the downlinksignals and radiate the downlink signals to a number of differentwireless devices, such as (not limited to) cellular phones, operating inthe environment of the DAS 10. A non-limiting example of a remoteantenna unit is a universal access point.

A group of one or more remote antenna units 18 a-h can service acoverage zone. Each coverage zone can be a geographical area in the DAS10 environment where certain wireless devices can communicate with thegroup of remote antenna units. For example, the remote antenna units 18a-d can be included in a coverage zone servicing a first area wherewireless devices are located and the remote antenna units 18 e-h can beincluded in a coverage zone servicing a different area where wirelessdevices are located.

In an uplink direction, the remote antenna units 18 a-h can receiveuplink RF signals, convert them to digital data streams, and provide theuplink digital data streams to the unit 14 or the extension units 16a-b. The extension units 16 a-b can combine uplink digital data streamsinto combined digital data streams, such as band streams, and providethe combined digital data streams to the unit 14. In some aspects, theunit 14 can convert uplink digital data streams received from the remoteantenna units 18 a-h or the extension units 16 a-b into uplink RFsignals. The unit 14 can provide the uplink RF signals to the basestations 12 a-n. In other aspects, the unit 14 can convert uplinkdigital data streams received from the remote antenna units 18 a-h intodigital signals formatted for transmission to the base stations 12 a-nthat communicate using digital signals, in a standardized digital formator otherwise.

The unit 14, extension units 16 a-b, and remote antenna units 18 a-h cancommunicate via communication transport links 28 a-j. A communicationtransport link can include one or a series of physical connections overwhich a remote antenna unit can communicate with the unit 14 directly orthrough an extension unit. A communication transport link can includeany type of communication medium capable of transporting signals betweenthe unit 14, the extension units 16 a-b, and the remote antenna units 18a-h. Each of the communication transport links 28 a-j can have a maximumavailable bandwidth or be associated with a maximum number of digitaldata streams that can be provided over the communication transport link.The maximum available bandwidth or a maximum number of digital datastreams can be determined from the type of communication medium used forthe communication transport link.

Although the DAS 10 is depicted as including one unit 14, two extensionunits 16 a-b, and eight remote antenna units 18 a-h, any number(including one) of each can be used. For example, a typical DAS 10 mayinclude dozens of extension units and hundreds of remote antenna units.

The DAS 10 can also include a configuration module 26 disposed in theunit 14. In other aspects, the configuration module 26 can be disposedin a system controller external to the unit 14 that can control the unit14.

The configuration module 26 can determine a plan for configuring thecommunication transport links 28 a-j between various components of theDAS 10. The configuration module 26 can output the plan to the DAS 10 orto a display via a graphical user interface. The outputted plan can beused to select the communication transport links 28 a-j over which theunit 14 provides the band sets to the remote antenna units. In someaspects, outputting the plan can include the unit 14 automaticallyconfiguring the communication transport links 28 a-j. In other aspects,the plan is outputted to a user via the graphical user interface. Theuser can manually configure the communication transport links 28 a-jusing the plan.

FIG. 2 depicts an example of the configuration module 26. Theconfiguration module 26 may be any device that can process data andexecute code that is a set of instructions to perform actions. Theconfiguration module 26 includes a processor 202, a memory 204, a bus206, and an input/output (I/O) interface 208. The memory 204 includes aconfiguration engine 210.

The processor 202 can execute code stored on a computer-readable medium,such as the memory 204, to cause the configuration module 26 todetermine a plan for configuring the communication transport links 28a-j in the DAS 10. Non-limiting examples of a processor 202 include amicroprocessor, an application-specific integrated circuit (“ASIC”), afield-programmable Gate Array (“FPGA”), or other suitable processor. Theprocessor 202 may include one processor or any number of processors.

The processor 202 can access code stored in the memory 204 via a bus206. Memory 204 may be any non-transitory computer-readable mediumcapable of tangibly embodying code and can include electronic, magnetic,or optical devices. Non-limiting examples of a memory 204 include randomaccess memory (RAM), read-only memory (ROM), magnetic disk, an ASIC, aconfigured processor, or other storage device. Bus 206 may be any devicecapable of transferring data between components of the configurationmodule 26. Bus 206 can include one device or multiple devices.

Instructions can be stored in the memory 204 as executable code. Theinstructions can include processor-specific instructions generated by acompiler and/or an interpreter from code written in any suitablecomputer-programming language, such as C, C++, C#, Visual Basic, Java,Python, Perl, JavaScript, and ActionScript.

The configuration module 26 can receive through an I/O interface 208inputs such as characteristics of the signals communicated through theDAS 10 and the hardware capabilities of the components of DAS 10. Theconfiguration module 26 can store the inputs in the memory 204. In someaspects, the inputs are received via a graphical user interface that maybe displayed on a separate computing device or on a display associatedwith the configuration module 26. In addition, data files includingvarious types of data can be stored in the memory 204. Such data caninclude hardware capabilities associated with various components of theDAS 10, such as the maximum bandwidth or maximum number of digital datastream that can be provided over certain types of communication mediumsused for communication transport links 28 a-j.

The instructions can include the configuration engine 210. When executedby the processor 202, the configuration engine 210 can determine theplan for configuring the communication transport links 28 a-j, asexplained in more detail below. The configuration engine 210 can alsogenerate control signals for configuration module 26 to provide to theunit 14.

This exemplary system configuration is provided to illustrateconfigurations of certain aspects. Other configurations and examples mayof course be utilized.

FIG. 3 depicts a flow chart illustrating a process 300 for configuringcommunication transport links according to one aspect. The process 300is described with reference to the DAS 10 depicted in FIG. 1 and thesystem implementation of configuration module 26 depicted in FIG. 2.Other implementations and processes, however, are possible.

In block 310, the configuration engine 210 determines characteristics ofthe signals to be communicated using the DAS 10. Non-limiting examplesof signal characteristics include the frequency band of a signal, thebandwidth of the signal, a digital bandwidth for transporting a digitalrepresentation of the signal, a frequency occupancy of each signal, etc.The frequency band and bandwidth may be associated with the type ofsignal received from each of the base stations 12 a-n, such as signalstransmitted using a Global System for Mobile Communications (“GSM”)standard. Another signal characteristic that may be received byconfiguration engine 210 is the coverage zone to which the signal is tobe provided.

In some aspects, the configuration engine 210 can receive inputs via theI/O interface 208 regarding the signal characteristics. For example, theconfiguration engine 210 may receive inputs for one or more of thesignals regarding the coverage zone to which the signal or signals areto be provided. In other aspects, the configuration engine 210 canreceive the signal characteristics from the unit 14. For example, theunit 14 may determine the frequency band and bandwidth associated withthe signals received from the base stations 12 a-n. The configurationengine 210 can receive the bandwidths and frequency bands from the unit14. In other aspects, the configuration engine 210 can receive thesignal characteristics from the base stations 12 a-n.

In block 320, the configuration engine 210 determines a hardwarecapability of the DAS 10. Non-limiting examples of the hardwarecapability include the available bandwidth for each of the communicationtransport links 28 a-j in the DAS 10, the maximum number of digital datastreams capable of being provided over each of the communicationtransport links 28 a-j, and the association of communication transportlinks with the remote antenna units in a coverage zone. In some aspects,the configuration engine 210 can determine the hardware capability basedon inputs received via the I/O interface 208. In other aspects, theconfiguration engine 210 can determine the hardware capability byrequesting information about each of the communication transport links28 a-j from the unit 14 and/or extension units 16 a-b. Such informationcan include the types of communication mediums used by the communicationtransport links 28 a-j. The configuration engine 210 can reference adata file stored in the memory 204 containing a table that lists thebandwidths associated with different types of communication mediums.

In block 330, the configuration engine 210 determines a plan forconfiguring the DAS 10 based on the characteristics of the signals andthe hardware capability of the DAS 10. The plan can include configuringthe communication transport links between a unit 14 and a remote antennaunit, between a unit 14 and an extension unit, and/or between anextension unit and a remote antenna unit. Determining a configurationplan can include assigning signals to the communication transport links28 a-j. Assigning the signals can include identifying whichcommunication transport links 28 a-j are available to provide a signalto a coverage zone. In some aspects, the configuration engine 210 candetermine the available communication transport links from inputsreceived via the I/O interface 208 of the configuration module 26. Inother aspects, the configuration engine 210 can determine the availablecommunication transport links by requesting information about thecommunication transport links from the unit 14 and/or extension units 16a-b. Assigning the signals can also include determining whether thehardware capability, such as the available bandwidth or maximum numberof digital data streams, of the identified communication transport linksallows the signal to be provided to the coverage zone over theidentified communication transport links.

Signals can be grouped into coverage sets in assigning signals to thecommunication transport links 28 a-j. Each coverage set can include acollection of signals to be provided to a coverage zone. Each coverageset can be associated with one or more coverage zones. Determining theplan for configuring the communication transport links 28 a-j caninclude assigning a coverage set to one or more communication transportlinks 28 a-j over which signals in the coverage set are to be providedone or more coverage zones associated with the coverage set. In someaspects, signals can be grouped into coverage sets and assigned to thecoverage zones based on inputs received via the I/O interface 208.

In block 340, the configuration engine 210 outputs the plan. Outputtingthe plan can include providing the plan via the I/O interface 208 fordisplay in a graphical user interface to a user. The user can configurethe unit 14 and the extension units 16 a-b based on the plan provided byconfiguration engine 210. In other aspects, the configuration engine 210can generate a control signal for configuring the communicationtransport links 28 a-j. The configuration module 26 can provide thecontrol signal to the unit 14 for determining, for each signal, thecommunication transport links over which to provide the signal.

FIG. 4 depicts a model of relationships between signals and coveragezones generated by the configuration engine 210 for use in formulating aconfiguration plan. The configuration engine 210 can group signals thatthe unit 14 receives from the base stations 12 a-n into band sets 402a-f, group the band sets 402 a-f into coverage sets 404 a-d, and assigncoverage sets 404 a-d to the communication transport links 28 a-j fordelivery to the coverage zones 408 a-e. Each of the coverage sets 404a-d can include one or more band sets 402 a-f. Coverage sets can includethe same band sets (e.g., coverage sets 404 a-b) or different band sets(e.g. coverage sets 404 c-d).

The configuration engine 210 can receive an identification of each ofthe coverage zones 408 a-e. Each of the coverage zones 408 a-e caninclude a subset of the remote antenna units, depicted as darkenedcircles in FIG. 4, of the DAS 10. Each of the coverage zones 408 a-e canservice a physical area within the environment of the DAS 10.

The configuration engine 210 can receive characteristics about thesignals that unit 14 receives from base stations 12 a-n. Thecharacteristics can include, for each signal, a bandwidth and one ormore of the coverage zones 408 a-e to which the signal is to beprovided. In some aspects, the configuration engine 210 can receive anassignment, for each signal, to a destination coverage zone to which thesignal is to be provided. The configuration engine 210 can receive theassignment as input via the I/O interface 208. For example, theconfiguration engine 210 may receive, via the I/O interface 208, anidentification of coverage zones and a command that signals at specificfrequency bands or received from specific base stations are to beprovided to specific coverage zones. In other aspects, the configurationengine 210 can receive the identification of coverage zones andassignments of signals to the destination coverage zones from automationalgorithms for assigning signals to the coverage zones 408 a-e. Theautomation algorithms can be stored in the memory 204 and executed byprocessor 202.

The configuration engine 210 can also receive a frequency band andassociated bandwidth for each of the signals received from the basestations 12 a-n. For example, the base stations 12 a-n may providesignals in the GSM-900 band of 935-960 MHz with a bandwidth of 200 kHz,in the GSM-1800 band of 1704-1734 MHz with a bandwidth of 200 kHz, inthe GSM-1900 band of 1930-1990 MHz with a bandwidth of 200 kHz, or anyfrequency bands and bandwidths used by one or more telecommunicationsystems using the DAS 10.

The configuration engine 210 can group the signals from the basestations 12 a-n into band sets 402 a-f. In some aspects, each of theband sets 402 a-f can be associated with a different frequency band. Forexample, the band set 402 a may be associated with a GSM-900 band, theband set 402 b may be associated with a GSM-1800 band, the band set 402c may be associated with a GSM-1900 band, etc.

The configuration engine 210 can combine the signals in a band set intoa band stream representing the band set. Combining the signals in a bandset into a band stream can reduce the number of digital data streamsused to provide a band set to a coverage zone. Reducing the number ofdigital data streams provided to a coverage zone can reduce the numberof communication transport links used for communicating signals betweena unit 14 and the coverage zone.

The configuration engine 210 can group each of the band sets 402 a-finto one or more coverage sets 404 a-d. Each of the coverage sets 404a-d can also be associated with one or more coverage zones 408 a-e. Eachof the coverage sets 404 a-d can include the band sets that are to beprovided to a coverage zone.

For example, the configuration engine 210 can receive input assigningthe band sets 402 a-c to coverage zones 408 a-c, band sets 402 b, 402 c,402 e to coverage zone 408 d, and band sets 402 c, 402 d, 402 f tocoverage zone 408 e. Based on the input, the configuration engine 210can assign each of the band sets 402 a-c to coverage sets 404 a-b, eachof the band sets 402 b, 402 c, 402 e to coverage set 404 c, and the bandsets 402 c, 402 d, 402 f to coverage set 404 d. The configuration engine210 can associate the coverage set 404 a with the coverage zone 408 a,the coverage set 404 b with the coverage zones 408 b-c, the coverage set404 c with the coverage zone 408 d, and the coverage set 404 d with thecoverage zone 408 e. The configuration engine 210 can determine andoutput a plan to configure the communication transport links fortransporting data streams representing the band sets 402 a-f based onthe association between coverage sets 404 a-d and coverage zones 408a-e.

FIG. 5 illustrates a process 500 for configuring the communicationtransport links 28 a-j of the DAS 10 based on the association ofcoverage sets 404 a-d and coverage zones 408 a-e according to oneaspect.

In block 510, the configuration engine 210 receives bandwidths forsignals received from base stations 12 a-n. In some aspects, theconfiguration engine 210 detects a bandwidth of a signal by analyzingthe signal. In other aspects, the configuration engine 210 can referencea data file in the memory 204 that includes information about thesignals received from the base stations 12 a-n. The data file canidentify the bandwidths of signals provided by each of the base stations12 a-n.

In block 520, the configuration engine 210 receives an identification ofcoverage zones 408 a-e to which the signals are to be provided overcommunication transport links 28 a-j.

In block 530, the configuration engine 210 receives an association ofthe coverage zones 408 a-e with one or more of the coverage sets 404a-d. Each of the coverage sets 404 a-d can include a sub-set of bandsets, each represented by a data stream of at least some of the signalsreceived from the base stations 12 a-n. The data streams representingband sets in a coverage set can be provided to one or more coveragezones associated with the coverage set.

In block 540, the configuration engine 210 determines an availablebandwidth for each of the communication transport links 28 a-j. Thebandwidth of a communication transport link may be based on the type ofcommunication medium for the communication transport link. In someaspects, the configuration engine 210 can use a discovery function todetermine the bandwidth for each communication transport link.

In block 550, the configuration engine 210 determines a plan forconfiguring the communication transport links 28 a-j to provide thecoverage sets to the coverage zones. The configuration engine 210 candetermine the plan based on the association between the coverage setsand the coverage zones, the bandwidth for each of the signals includedin the coverage sets 404 a-d, and the available bandwidth for each ofthe communication transport links 28 a-j.

Determining the plan can include determining how many communicationtransport links a unit 14 can use to provide a coverage set to adestination coverage zone. The configuration engine 210 can determine ifthe available bandwidth of a single communication transport link betweenthe unit 14 and the destination coverage zone is sufficient for anentire coverage set to be provided over the communication transportlink. The available bandwidth of the communication transport link issufficient if the total bandwidth associated with a coverage set doesnot exceed the available bandwidth of the communication transport link.The configuration engine 210 can determine the total bandwidthassociated with a coverage set by summing the bandwidths of each bandset included in a coverage set. The bandwidth of each band set can bedetermined by summing the bandwidths of each band stream included in theband set. The bandwidth of each band stream can be determined bycomputing the difference between the highest and lowest frequencies ofsignals included in the band stream. If the available bandwidth of asingle communication transport link is not sufficient for an entirecoverage set to be provided over the communication transport link, theconfiguration engine 210 can assign the signals in the coverage setacross multiple communication transport links. Each of the communicationtransport links between the unit 14 and the destination coverage zonecan be used to provide one or more of the signals to the destinationcoverage zone.

In some aspects, the configuration engine 210 can determine the planbased on the bandwidth for each band stream representing a band set. Theconfiguration engine 210 can assign band streams representing band sets,rather than the digital data streams representing individual signals,across multiple communication transport links based on the bandwidths ofthe band streams. The configuration engine 210 can determine thebandwidth of a band stream by computing the difference between thehighest and lowest frequency signals in the band set represented by theband stream.

In block 560, the configuration engine 210 outputs the plan to theconfiguration module 26. In some aspects, the configuration module 26can generate and provide a control signal to the unit 14 for configuringthe communication transport links 28 a-j based on the plan. In otheraspects, the configuration module 26 can provide the plan to a user viaa graphical interface. The user can configure the communicationtransport links 28 a-j based on the plan.

FIG. 6 depicts additional details of an aspect of block 550 from FIG. 5.

In block 610, the configuration engine 210 sorts the band streams in theselected coverage set by bandwidth from largest to smallest. Forexample, if the band streams in coverage set 404 a represent a band set402 a with bandwidth of 5 MHz, a band set 402 b with a bandwidth of 1.25MHz, and a band set 402 c with a bandwidth of 200 kHz, the band streamscan be assigned to communication transport links in the order of bandset 402 a, band set 402 b, and band set 402 c.

In block 620, the configuration engine 210 selects the unassigned bandstream with the largest bandwidth from the coverage set.

In block 630, the configuration engine 210 selects the first availablecommunication transport link between a coverage zone and a unit 14. Forexample, in FIG. 1, a first coverage zone can include the extensionunits 16 a-b and remote antenna units 18 a-d, while a second coveragezone can include the remote antenna units 18 e-h. A coverage set 404 amay be assigned to the first coverage zone. A unit 14 may communicatewith the first coverage zone via the communication transport links 28 a,28 d. The configuration engine 210 can select either of thecommunication transport links 28 a, 28 d for the unit 14 to provide thecoverage set 404 a to the first coverage zone in block 630.

In block 640, the configuration engine 210 determines whether theselected communication transport link can transport the selected bandstream. In some aspects, the selected communication transport linkcannot transport the selected band stream if the bandwidth of theselected band stream exceeds the available bandwidth of the selectedcommunication transport link. The configuration engine 210 can determinewhether the bandwidth of the selected band stream is less than theremaining available bandwidth for the selected communication transportlink by comparing the total bandwidth of the band streams assigned tothe selected communication transport link, the total bandwidth of thecommunication transport link, and the bandwidth of the selected bandstream. If the bandwidth of the selected band stream is greater than theremaining available bandwidth for the selected communication transportlink, then the selected communication transport link cannot transportthe selected band stream.

In other aspects, the selected communication transport link cannottransport the selected band stream if the number of band streams alreadyassigned to the selected communication transport link is equal to themaximum number of digital data streams that can be provided over theselected communication transport link. The configuration engine 210 candetermine the maximum number of digital data streams by referencing adata file stored in the memory 204. The data file can includeinformation about the number of digital data streams that can beprovided over various types of communication transport links 28 a-j. Ifthe number of band streams assigned to the communication transport linkis equal to the maximum number of digital data streams, then theselected communication transport link cannot transport the selected bandstream.

If the selected communication transport link cannot transport theselected band stream, the configuration engine 210 determines whetheranother communication transport link is available in block 650. Ifanother communication transport link is available, the process selectsthe next available communication transport link in block 652 and returnsto block 640. In the example described above with respect to block 630,between unit 14 and a coverage zone may be multiple communicationtransport links capable of carrying signals between unit 14 and remoteantenna units in the coverage zone. The unit 14 may be able to providethe band streams representing the band sets 402 a, 402 b of a coverageset 404 a to the first coverage zone 408 a over the one or more of thecommunication transport links. The unit 14 may not be able to providethe band stream representing the band set 402 c to the first coveragezone 408 a over a first communication transport link. The configurationengine 210 can determine that a second communication transport link isavailable in block 650, select the second communication transport linkfor providing the band set 402 c in block 652, and continue the processof assigning the band streams to the communication transport links inblock 640.

If no other communication transport links are available, theconfiguration engine 210 terminates the process and outputs an errormessage in block 660. The configuration engine 210 can provide the errormessage via the I/O interface 208 to be displayed at a graphical userinterface. An error message can indicate that the DAS 10 cannot providea coverage set to a destination coverage zone.

If the selected communication transport link can transport the selectedband stream, the configuration engine 210 assigns the selected bandstream to the selected communication transport link in block 670. Theconfiguration engine 210 can cause the assignment of the band stream tothe selected communication transport link to be stored in a data file inthe memory 204.

In block 680, the configuration engine 210 determines whether thecoverage set includes any remaining unassigned band streams. If thecoverage set includes any remaining unassigned band streams, the processreturns to block 620. In some aspects, the configuration engine 210 candetermine if any unassigned band streams exist by comparing theassignments of band streams to communication transport links stored inthe memory 204 with the band streams in each coverage set. If thecoverage set does not include any unassigned band streams, the plan forconfiguring the communication transport links 28 a-j is complete and theprocess terminates at block 690.

FIG. 7 depicts additional details of an aspect of block 550 from FIG. 5using common band sets, shared band sets, and zone-specific band sets.Common band sets can include band sets assigned to all coverage zones408 a-e. Shared band sets can include band sets assigned to more thanone but fewer than all coverage zones 408 a-e. Zone-specific band setscan include band sets that are assigned to only one of coverage zones408 a-e.

In block 702, the configuration engine 210 sorts the band streams in theselected coverage set by bandwidth from largest to smallest, as in block610 of the process depicted in FIG. 6.

In block 704, the configuration engine 210 groups into sub-sets the bandstreams of the selected coverage set. A first sub-set can include allband streams representing the common band sets (i.e., common bandstreams). One or more sub-sets can include all band streams representingshared band sets (i.e., shared band streams). The configuration engine210 can sort the sub-sets for shared band streams in decreasing order ofsub-set bandwidth. One or more sub-sets can include all band streamsrepresenting zone-specific band sets (i.e., zone-specific band streams).The configuration engine 210 can sort the sub-sets for zone-specificband streams in decreasing order of sub-set bandwidth.

In block 706, the configuration engine 210 determines whether anunassigned sub-set for common band streams is available. If so, theconfiguration engine 210 selects the sub-set for common band streams inblock 708.

In block 710, the configuration engine 210 selects the unassigned bandstream in the selected sub-set with the largest bandwidth, as in block620 of the process depicted in FIG. 6.

In block 712, the configuration engine 210 selects the first availablecommunication transport link between a unit 14 and a destinationcoverage zone, as in block 630 of the process depicted in FIG. 6.

In block 714, the configuration engine 210 determines whether theselected communication transport link can transport the selected bandstream, as in block 640 of the process depicted in FIG. 6.

If the selected communication transport link cannot transport theselected band stream, the configuration engine 210 determines whetheranother communication transport link is available in block 716. Ifanother communication transport link is available, the configurationengine selects the next available communication transport link in block718 and returns to block 714. The process continues until terminating atblock 720 or block 734. If no other communication transport links areavailable, the configuration engine 210 terminates the process andoutputs an error message in block 720.

If the selected communication transport link can transport the selectedband stream, the configuration engine 210 assigns the selected bandstream to the selected communication transport link in block 722, as inblock 670 of the process depicted in FIG. 6.

In block 724, the configuration engine 210 determines whether theselected sub-set includes any remaining unassigned band streams. If theselected sub-set includes any unassigned band streams, the processreturns to block 710 and continues until terminating at block 720 orblock 734.

If the configuration engine 210 determines in block 706 that nounassigned sub-set for common band streams is available or in block 724that the selected sub-set does not include any unassigned band streams,the configuration engine 210 determines if any unassigned sub-set forshared band streams is available in block 726. If so, the configurationengine 210 selects the unassigned sub-set for shared band streams withthe largest bandwidth in block 728 and returns to block 710. The processcontinues until terminating at block 720 or block 734. In some aspects,the configuration engine 210 can determine if any unassigned sub-setsare available by referencing a data file stored in the memory 204including the assignments of band streams and sub-sets to communicationtransport links.

If the configuration engine 210 determines in block 726 that nounassigned sub-set for shared band streams is available, theconfiguration engine 210 determines if any unassigned sub-set forzone-specific band streams is available in block 730. If so, theconfiguration engine 210 selects the unassigned sub-set forzone-specific band streams with the largest bandwidth in block 732 andreturns to block 710. The process continues until terminating at block720 or block 734. If the configuration engine 210 determines in block730 that no unassigned sub-set for zone-specific band streams isavailable, the plan for configuring the communication transport links 28a-j is complete and the process terminates at block 734.

In some aspects, the configuration engine 210 can use the processdepicted in FIG. 7 to configure the communication transport linksbetween a unit and an extension unit. For example, a unit maycommunicate with several extension units. If the extension unitscommunicate with remote antenna units in overlapping coverage zones,then each extension unit can be associated with one or more coveragezones. Each of the extension units may be associated with remote antennaunits that are separately located in all coverage zones, remote antennaunits that are separately located in more than one but fewer than allcoverage zones, or remote antenna units that are only in a singlecoverage zone.

In the circumstances described above, the configuration engine 210 canuse the process depicted in FIG. 7 to assign band streams tocommunication transport links between the unit and the extension units.When the configuration engine 210 selects the subset for common bandstreams in block 708, the available communication transport links inblocks 712-718 can be the communication links between the unit and theextension units associated with all coverage zones. When theconfiguration engine 210 selects a subset for shared band streams inblock 728, the available communication transport links in blocks 712-718can be the communication links between the unit and the extension unitsassociated with the coverage zones receiving the shared band streams.When the configuration engine 210 selects a sub-set for zone-specificband streams in block 732, the available communication transport linksin blocks 712-718 can be the communication links between the unit andthe extension units associated with the coverage zone receiving azone-specific band set.

The foregoing description of the aspects, including illustratedexamples, of the invention has been presented only for the purpose ofillustration and description and is not intended to be exhaustive or tolimit the invention to the precise forms disclosed. Numerousmodifications, adaptations, and uses thereof will be apparent to thoseskilled in the art without departing from the scope of this invention.

What is claimed is:
 1. A method for developing a configuration plan forcommunication transport links of a distributed antenna system, thedistributed antenna system having a unit in communication over thecommunication transport links with remote antenna units for one or morecoverage zones, the unit receiving a plurality of signals from at leastone base station, the method comprising: determining, for each signal ofthe plurality of signals, characteristics comprising a respectivefrequency occupancy of the signal, a respective coverage zone to whichto provide the signal, and a respective bandwidth for communicating thesignal via at least one of the communication transport links, whereinthe frequency occupancy comprises the minimum frequency component andthe maximum frequency component of the signal; determining a respectiveavailable bandwidth of each of the communication transport links betweenthe unit and the remote antenna units that transmit signals in the oneor more coverage zones; generating the configuration plan based on thedetermined characteristics of the plurality of signals and thedetermined respective available bandwidth of each of the communicationtransport links, wherein the configuration plan includes assignments ofdifferent subsets of the plurality of signals to the communicationtransport links for transmitting the subsets of the plurality of signalsto the one or more coverage zones; and outputting the configurationplan.
 2. The method of claim 1, wherein determining the respectivecoverage zone for each signal comprises determining an association ofcoverage zones with respective coverage sets, wherein each coverage zonerepresents a subset of the remote antenna units, wherein each coverageset represents a subset of signals of the plurality of signals that areto be transported to a common coverage zone.
 3. The method of claim 2,wherein the subset of signals of the plurality of signals comprises bandsets, each of the band sets comprising a set of signals having anassociation with the common coverage zone, wherein each of the band setsis represented by a respective band stream.
 4. The method of claim 3,further comprising generating each band stream by combining a respectiveset of signals.
 5. The method of claim 4, wherein generating theconfiguration plan comprises: for each band set, determining arespective band set bandwidth for communicating a digital representationof all signals in the band set based on the frequency occupancy of allsignals in the band set; and generating the configuration plan based onthe determined respective available bandwidth of each communicationtransport link, the band set bandwidth of each band set, andassociations between the coverage zones and the respective coveragesets, wherein the configuration plan further specifies the communicationtransport links via which to deliver band streams representing the bandsets to the one or more coverage zones.
 6. The method of claim 3,wherein determining the association of coverage zones with respectivecoverage sets comprises, for each signal of the plurality of signals:receiving a respective coverage zone to which to provide the signal;assigning the signal to a respective band set having a plurality ofsignals associated with a respective band and the respective coveragezone, the respective band set being represented by a respective bandstream having a respective band stream bandwidth; and assigning therespective band set to a respective coverage set, the respectivecoverage set being associated with the respective coverage zone andcomprising a plurality of band streams.
 7. The method of claim 3,wherein determining the respective coverage zone for each signal of theplurality of signals comprises: associating each coverage zone of theone or more coverage zones with a subset of the remote antenna units;for each signal of the plurality of signals, determining a bandassociated with the signal; and receiving an identification of arespective coverage zone to which to provide the signal; determiningband sets based on the one or more coverage zones and bands associatedwith the plurality of signals, each of the band sets representing asubset of the plurality of signals associated with respective coveragezone; determining one or more coverage sets based on the band sets andthe one or more coverage zones, each coverage set being associated withat least one of the one or more coverage zones and representing a subsetof the band sets.
 8. A distributed antenna system, comprising: aplurality of remote antenna units grouped into one or more coveragezones, each coverage zone comprising a subset of the remote antennaunits; a unit in communication over communication transport links withthe plurality of remote antenna units for one or more coverage zones,the unit configured to receive a plurality of signals from at least onebase station, the unit comprising a configuration module, wherein theconfiguration module is configured to: determine, for each signal of theplurality of signals, characteristics comprising a respective frequencyoccupancy of the signal, a respective coverage zone to which to providethe signal, and a respective bandwidth for communicating the signal viaat least one of the communication transport links, wherein the frequencyoccupancy comprises the minimum frequency component and the maximumfrequency component of the signal; determine a respective availablebandwidth of each of the communication transport links between the unitand the remote antenna units that transmit signals in the one or morecoverage zones; generate a configuration plan based on the determinedcharacteristics of the signals and the determined respective availablebandwidth of each of the communication transport links, wherein theconfiguration plan includes assignments of different subsets of thereceived signals to the communication transport links for transmittingthe subsets of the received signals to the one or more coverage zones;and output the configuration plan.
 9. The distributed antenna system ofclaim 8, wherein determining the respective coverage zone for eachsignal comprises receiving an association of coverage zones withcoverage sets, wherein each coverage zone represents the subset of theremote antenna units, wherein each coverage set represents a subset ofsignals of the plurality of signals that are to be transported to acommon coverage zone.
 10. The distributed antenna system of claim 9,wherein the subset of signals of the plurality of signals comprises bandsets, each of the band sets comprising a set of signals having anassociation with the common coverage zone, wherein each of the band setsis represented by a band stream.
 11. The distributed antenna system ofclaim 10, wherein the configuration plan is generated based onbandwidths for communicating digital representations of the band sets,wherein a respective bandwidth of each band set is determined by thefrequencies of the signals in the set of signals.
 12. The distributedantenna system of claim 11, wherein the configuration module is furtherconfigured to generate the configuration plan based on: a number ofcommunication transport links between a remote antenna unit and theunit; a determination of whether one or more communication transportlinks are shared by two or more remote antenna units; and a maximumnumber of band streams capable of being carried by the communicationtransport links.
 13. The distributed antenna system of claim 10, whereindetermining the respective coverage zone for each signal of theplurality of signals comprises: associating each coverage zone of theone or more coverage zones with a subset of the remote antenna units;for each signal of the plurality of signals, determining a bandassociated with the signal; and receiving an identification of acoverage zone of the plurality of coverage zones to which to provide thesignal; determining band sets based on the one or more coverage zonesand bands associated with the plurality of signals, each of the bandsets representing a subset of the plurality of signals; determining oneor more coverage sets based on the band sets and the plurality ofcoverage zones, each coverage set being associated with at least one ofthe plurality of coverage zones and representing a subset of the bandsets.
 14. The distributed antenna system of claim 10, wherein generatingthe configuration plan comprises: for each band set, determining arespective band set bandwidth based on the bandwidth of each signal inthe band set; and determining the configuration plan based on thedetermined respective available bandwidth of each communicationtransport link, the respective band set bandwidth of each band set, andassociations between the coverage zones and the respective coveragesets, wherein the configuration plan further specifies the communicationtransport links via which to deliver band streams representing the bandsets to the coverage zones.
 15. A distributed antenna system comprising:a unit configured to receive a plurality of signals from a base stationand communicate the plurality of signals to remote antenna units for aplurality of coverage zones via communication transport links of thedistributed antenna system; a processor disposed in the unit andconfigured to: determine, for each signal of the plurality of signals,characteristics comprising a respective frequency occupancy of thesignal, a respective coverage zone to which to provide the signal, and arespective bandwidth for communicating the signal via at least one ofthe communication transport links, wherein the frequency occupancycomprises the minimum frequency component and the maximum frequencycomponent of the signal; determine a respective available bandwidth ofeach of the communication transport links between the unit and theremote antenna units that transmit signals in the plurality of coveragezones; generate a configuration plan based on the determinedcharacteristics of the signals and the determined respective availablebandwidth of each of the communication transport links, wherein theconfiguration plan includes assignments of different subsets of thereceived signals to the communication transport links for transmittingthe subsets of the received signals to the plurality of coverage zones;and output the configuration plan.
 16. The distributed antenna system ofclaim 15, wherein determining the respective coverage zone for eachsignal comprises receiving an association of coverage zones withcoverage sets, wherein each coverage zone represents the subset of theremote antenna units, wherein each coverage set represents a subset ofsignals of the plurality of signals that are to be transported to acommon coverage zone.
 17. The distributed antenna system of claim 16,wherein the subset of signals of the plurality of signals comprise bandsets, each of the band sets comprising a set of signals having anassociation with the common coverage zone, the band set beingrepresented by a band stream.
 18. The distributed antenna system ofclaim 17, wherein the configuration plan is generated based onbandwidths for communicating digital representations of the band sets,wherein a respective bandwidth of each band set is determined by thefrequencies of the signals in the set of signals.
 19. The distributedantenna system of claim 18, wherein the processor is further configuredto generate the configuration plan based on: a number of communicationtransport links between a remote antenna unit and the unit; adetermination of whether one or more communication transport links areshared by two or more remote antenna units; and a maximum number of bandstreams capable of being carried by the plurality of communicationtransport links.
 20. The distributed antenna system of claim 17, whereindetermining the respective coverage zone for each signal of theplurality of signals comprises: associating each coverage zone of theplurality of coverage zones with a subset of the remote antenna units;for each signal of the plurality of signals, determining a bandassociated with the signal; and receiving an identification of acoverage zone of the plurality of coverage zones to which to provide thesignal; determining band sets based on the plurality of coverage zonesand bands of the plurality of signals, each of the band setsrepresenting a subset of the plurality of signals; determining one ormore coverage sets based on the band sets and the plurality of coveragezones, each coverage set being associated with at least one of theplurality of coverage zones and representing a subset of the band sets.21. The distributed antenna system of claim 10, wherein generating theconfiguration plan comprises: for each band set, determining a band setbandwidth based on the bandwidth of each signal in the band set; anddetermining the configuration plan based on the determined respectiveavailable bandwidth of each communication transport link, the band setbandwidth of each band set, and associations between the plurality ofcoverage zones and the respective coverage sets, wherein theconfiguration plan further specifies the communication transport linksvia which to deliver band streams representing the band sets to theplurality of coverage zones.